EP0147611A2 - Method and apparatus for regulating the rotational speed of a combustion engine - Google Patents

Abstract

System for speed control in an internal combustion engine, the speed of which is guided, on the one hand, by an idle charge control and, on the other hand, by a thrust cut-off circuit for the relevant operating areas, with means which thereby prevent undesired thrust cut-off when the engine speed is deliberately caused by the idle charge control, so that the actual value of the engine The idle charge control generated actuator control signal compared with a threshold value and the overrun cutoff function is blocked when the threshold value is exceeded. The use of a PID controller in the idle charge control also results in a dynamic behavior of the reinsertion speed of the overrun fuel cutoff function.

Description

State of the art

The invention is based on a method and a device for speed control in an internal combustion engine in each case according to the type of the main claim or the first device claim.

Devices for speed control in internal combustion engines are known; For example, it is common to provide an idle charge control (LFR) that can operate on an air bypass parallel to the throttle valve of the internal combustion engine - usually a two-winding rotary actuator. Taking into account the current actual speed of the internal combustion engine, a target speed and other peripheral information, such an idle charge control, implemented in analog or digital technology, is able to maintain perfect idling of the internal combustion engine, which is important, for example, in shunting or overrun mode and when changing from this to idling.

On the other hand, it is known in internal combustion engines to interrupt the fuel supply during operation when the throttle valve is closed at higher and higher speeds, ie the internal combustion engine is in the so-called overrun mode. Such overrun operation is also present when an internal combustion engine has a higher rotational speed than the position of the throttle valve in the gasoline engine or the amount of fuel injected, for example in a diesel engine. If the internal combustion engine is in overrun mode, work is not desired and therefore the amount of fuel supplied to the internal combustion engine is usually reduced or completely set to zero (thrust cut-off SAS) via the respective fuel supply device (carburetor, injection systems or the like).

However, it cannot be ruled out that problems can arise, especially when both systems, which necessarily operate independently of one another, are used in an internal combustion engine, for example by the LFR actuator being opened wide by appropriate control by the controller of the idle charge control due to operational considerations to be taken into account Circumstances (e.g. start or possibly excessive warm-up) and the actual engine speed briefly exceeds the cut-off speed specified for the thrust cut-off circuit. In this case, both systems feel responsible; the thrust cut-off function sets in, so that it is, for example, and under certain extreme conditions sawing (uncontrolled vibration behavior) can occur. In very extreme circumstances and when the machine is cold, the engine can even stop.

The invention is therefore based on the object of preventing an undesirable interaction of the two systems, possibly leading to malfunctions, in an internal combustion engine equipped with overrun cutoff and idle charge control.

Advantages of the invention

This object is achieved by the method according to the invention and the device according to the invention each with the characterizing features of the main claim or the first device claim, which results in the advantage that thrust cutting is always prohibited when the actuator opening of the idle charge control is the cause of the speed increase is what causes thrust cutting. It is therefore prevented under all circumstances that the simultaneous functions of the idle charge control and the thrust cutting cause sawing in the speed curve of the internal combustion engine; the invention also has a compensating effect and eliminates faults perfectly where previously particularly critical conditions could occur, that is to say directly after the starting process or after disengaging, when the vehicle has been braked below the idling speed.

In order to meet all requirements for perfect idling of an internal combustion engine and in particular to be able to use safe rescue functions, If the internal combustion engine threatens to run out, the idle charge control has a controller with PID control behavior, such a controller using analog technology or, which is currently preferred, based on digitally operating systems. This always present PID behavior of the idle charge control results in a further advantage of the present invention, which lies in the fact that the reinsertion speed of the thrust cut-off becomes dynamic. If one looks at the situation from the side of the thrust cut-off, this means that when the speed drops rapidly, fuel is supplied again at a higher reinstallation speed, that is to say the fuel is injected again at the injection system than at a slowly falling speed. The reason for this is that the magnitude of the calculated actuator control signal _{T is} all the greater due to the provision of the D component in the PID behavior of the idle charge controller. the faster the engine speed drops. As a result of the concept according to the invention, this calculated _{T is} compared with a predefined _T threshold and thrust cutting is prohibited if the calculated _{T is} greater than the threshold, as a result of this it follows that the calculated _T is much more likely when the engine speed drops rapidly ( D component) exceeds the threshold value and therefore the thrust cut-off function is also rather blocked. The invention therefore intervenes in its basic concept right up to the function of the thrust cut-off circuit, thereby designing the thrust cut-off dynamically without requiring additional circuit elements and components.

drawing

An embodiment of the invention is shown in the drawing and is explained in more detail in the following description. The drawing shows a block diagram only for illustration and a highly schematic basic structure of an idle charge control and a fuel cut-off system as well as the interaction of these two systems realized by the invention.

Description of the embodiments

In the drawing, the invention is shown on the basis of discrete circuit blocks of a block diagram which indicates idle charge control and thrust cut-off circuit in this respect also realized by means of discrete components or assemblies. However, it goes without saying and is within the scope of the invention, and it is even a preferred embodiment of the present invention to implement the entire system in particular with the aid of means which generate corresponding control signals on a digital basis and are subjected to a corresponding interaction. This includes in particular the program-controlled training of microprocessors with corresponding output systems, actuators and a sensor input circuit, microcomputers, but also systems on an analog basis. '

The description given below of a preferred exemplary embodiment is therefore to be evaluated in particular with regard to the functional sequence and only uses the reference to the individual circuit blocks For a better understanding.

The area of the idle charge control is grouped in the drawing around a logic control circuit, a microcomputer, a microprocessor or the like, which is designated by 10 and outputs the actuator control signal _' , which is designated by _T , at its output connection 10a.

In a special application and when the central processing unit 10 of the idle charge controller is designed as a microcomputer, this peripheral device also has the following modules: an input block 11, via which signals to be processed, such as the actual value of the current speed n _ist ', a speed setpoint n _should and a temperature specification is supplied via the outside temperature. Two further input blocks 12 and 13 are provided which, in the case of a microcomputer as a controller, are designed immediately as analog-digital converters and supply operating status information about the respective engine temperature and the battery voltage. An external memory 14 supplies the central computer 10 with additional information which is stored for the generation of the actuator control signal. The microcomputer 10 is a PID controller in terms of its construction and design, and uses the input parameters to create a required basic duty cycle for the actuator control signal, including appropriate correction variables and querying the external data memory 14. The actuator control signal passes via an output stage 15 and an intermediate circuit block 16, which the shutdown for safety reasons - this also includes circuit elements 1.7 and 18, which together form a fail-safe safety circuit, but which need not be discussed further here Actuator 19.

In the preferred embodiment, the actuator is designed as a two-winding rotary actuator 19a, which controls the idle speed control one as air bypass ROS parallel to _D selklappe switched slider 19b, the desired passage cross section is determined by the duty ratio supplied to the two-winding rotary actuator pulse train as an actuator driving signal.

The fuel metering system for the internal combustion engine is here merely representative of all possible forms as a preliminary stage 20 (control multivibrator stage) for the generation of so-called tp preliminary pulses, which preliminary stage is supplied with an air mass or air quantity specification from an input block 21, in addition to the speed signal n of the internal combustion engine. The preliminary stage or control multivibrator stage 20 operates via an intermediate link stage 22 to a further stage of the fuel injection system, which can be referred to as a multiplier stage; however, the output signal of the overrun cutoff stage represented by block 30 also reaches logic stage 22, so that the pre-pulses t _p are suppressed when overrun cutoff stage 30 detects the operating status overrun of the internal combustion engine. Corresponding input signals (temperature signal & rM, speed signal n and an idle signal LL (throttle valve position signal)) are evaluated by the overrun cutoff stage. The invention now begins at this point and first detects the size or amplitude of the actuator control signal _T generated by the PID controller of the idle charge control. If this signal is generated analogously, this can be fed immediately to the one input of a comparator or comparator 40; if the actuator control signal _{T is} modulated in its duty cycle, then a simple integrating block 41 can be interposed in order to gain an analog value if it is assumed that the invention works on an analog basis. However, it makes sense in the case of digital processing systems anyway, to also design the components which represent the invention and implement their function in the form of digital modules, or to integrate them directly into the overall system of idle charge control and overrun fuel cutoff by corresponding instructions to the respective computers, program memories and the like. Like. Be given. This preferably applies to those injection control units in which the idle charge control is simultaneously provided as a so-called integrated LFR.

The actuator control signal _T is compared with a suitable _T threshold, which is generated or specified by a block 42. It has proven to be useful and is therefore a preferred embodiment of the present invention to design the _T threshold as a function of the engine temperature and to select it in such a way that the engine speed resulting from the respective _{T is} in any case lower than the cut-off speed of the overrun cutoff function.

Therefore, if the comparator 40 determines that the effective actuator control signal _{T is} greater than the predetermined _T threshold, then this comparator also provides information that this increased engine speed caused by this is effectively due to a sensible reaction of the idle charge control, and the The comparator then generates a blocking signal at its output 40a, which is fed to an input 30a of the overrun fuel cutoff stage 30 and whose function blocks under these circumstances (actuator control signal _T greater than the predetermined _T threshold), that is to say prohibits the use of the overrun fuel cutoff function as a whole.

The invention is therefore able to cleanly separate the functions of the idle charge control from the overrun fuel cutoff, to prevent mutual influences and to ensure a smooth operation in the control of the instantaneous speed without oscillations in the smooth transition.

All features shown in the description, the following claims and the drawing can be essential to the invention both individually and in any combination with one another.

Claims (8)

1. Method for speed control in an internal combustion engine, whereby on the one hand an idle speed control (idle charge control LFR) maintains a lower minimum speed and on the other hand the fuel supply. Speeds above the idle speed and in the overrun mode of the motor vehicle is interrupted (thrust cut-off SAS), characterized in that the actuator control signal (f) of the idle speed control is compared with a predetermined _T- threshold value and the thrust cut-off function (SÄS) is blocked if the threshold value is exceeded. 2. The method according to claim 1, characterized in that the _T threshold value itself is a function of the engine temperature and is chosen so that the engine speed resulting from the respective _T threshold value is always less than the cut-off speed of the thrust cut-off function. 3. The method according to claim 1 or 2, characterized in that the re-insertion speed of the thrust cut-off function is set dynamically by the D component of the total idling charge controller having PID behavior in that the fuel supply again at a high re-insertion speed when the engine speed (s) drops rapidly is recorded because that Actuator control signal 7 calculated by the PID controller of the idle charge control reaches the limit value of the τ threshold earlier. 4.Device for speed control in an internal combustion engine, with an idle speed control (idle charge control LFR) to maintain a lower minimum speed and a thrust cutoff stage to block the fuel supply when the speed is above the idle speed and the internal combustion engine is simultaneously in the overrun mode, characterized in that a predetermined _T threshold value of the actuator control signal is formed for comparison with the instantaneous actual value of the actuator control signal (τ) generated by the idle charge control (LFR) and if the _T threshold value is exceeded, a lock signal of the thrust cut-off circuit (30) is fed to the internal combustion engine. 5. The device according to claim 4, characterized by a comparator (40) and a _T- threshold value of the actuator control signal generating circuit block (42) and a connecting line activated by a blocking signal from the comparator (40) to the fuel cutoff stage (30) when the actuator control signal exceeds the _T threshold. 6. Apparatus according to claim 4 or 5, characterized in that the controller of the idle charge control is a PID controller with such a dimensioned D component that the re-insertion speed of the thrust cut-off by the thrust cut-off circuit in the event of a rapid drop in speed (30) is dynamically raised to a higher reinsertion speed. 7. Device according to one of claims 4 to 6, characterized in that the _T threshold value is a function of the engine temperature (ϑ _M ).

Images